A Universe of Galaxies

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A Universe of Galaxies
James J Marie, Astronomy 2005
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Colliding Galaxies

• Collisions between galaxies
• are spectacular events which
• happen on a time scale of
• millions of years.
• When galaxies collide there
• is virtually no chance that any
• of the stars belonging to
• either galaxy will collide.
• However gravitational shock
• waves can ripple through the
• interstellar medium of one or
• both galaxies triggering the
• birth of new stars.
• The new stars can give rise to
• new structures and shapes.

James J Marie, Astronomy 2005
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Cartwheel Galaxy

• In the direction of the constellation Sculptor
  lies the aftermath of a galactic
• collision between an originally spiral galaxy
  and a smaller intruder galaxy.
• The intruder galaxy has left the scene long ago
  and the spiral galaxy has evolved
• into an expanding ring like shape.

• The cartwheel galaxy is 500
• million light years away and
• is 100,000 light years across.
• Gravitational distortions of the
• collision produced the ring like
• structure.
• The ring structure is composed
• of newly formed massive
• bright stars.

James J Marie, Astronomy 2005
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NGC 6872

• NGC 6872 is one of the
• largest known barred spirals
• measuring 750,000 light years
• across.
• The upper spiral arm shows
• an unusual amount of star
• formation.
• This star formation is thought
• to be associated with the
• passage of galaxy IC 4970
• through this part of NGC
• 6872.

James J Marie, Astronomy 2005
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Future Collision

• Because of local motion (also called peculiar
  motion), the Andromeda Galaxy
• is actually moving toward the Milky Way
  Galaxy.
• The Andromeda Galaxy and the Milky Way Galaxy
  will collide in about
• 3 billion years.

? Andromeda Galaxy
James J Marie, Astronomy 2005
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Galactic Mergers

• Occasionally colliding galaxies merge into a
  single galaxy.
• Some elliptical galaxies are thought to have
  formed from galactic collisions.

? NGC 1275

• A spiral galaxy is seen
• slicing through an
• elliptical galaxy.

James J Marie, Astronomy 2005
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Active Galaxies

• The centers or nuclei of some galaxies are
  tremendous sources of energy.
• This energy is radiated in the form of radio
  waves, visible light, x-rays, gamma
• rays and subatomic particles.
• The power radiated from the nuclei of some of
  these galaxies varies in time.
• Galactic nuclei have been observed to vary in
  brightness by 15 billion Suns in
• only a matter of 30 minutes!
• Such a galactic nucleus is called an Active
  Galactic Nucleus or AGN.
• The host galaxy of an AGN is called an active
  galaxy.

James J Marie, Astronomy 2005
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A Strange Blue Radio

• In the early 1960s Martin Schmidt discovered a
  source of radio waves in the
• sky called 3C273.
• This radio source appeared as a blue star in a
  telescope.

• An image of 3C273 taken in
• visible light from an optical
• telescope.

• The spectral lines of 3C273 seemed
• very odd because they didnt
• correspond the familiar spectral
• lines of known elements.

James J Marie, Astronomy 2005
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Quasars

• After puzzling over the spectral lines for
  several months, Schmidt realized
• that the spectral lines were simply emission
  lines from hydrogen but they
• were greatly redshifted.
• Upon measuring the redshift of 3C273, Schmidt
  realized that 3C273 was
• moving away from us at nearly 17 the speed of
  light!
• The luminosity-distance formula revealed that
  3C273 had a luminosity more
• than a trillion times that of the Sun!
• Other objects similar to 3C273 were discovered
  and called quasi-stellar radio
• sources or quasars for short.
• For several years quasars were very mysterious
  because no one could explain
• how so much energy could be radiated from a
  single star-like object.

James J Marie, Astronomy 2005
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Nature of Quasars

• Most quasars lie more than halfway to the
  cosmological horizon and are
• the farthest known objects in the universe.
• The light from these quasars was emitted when
  the universe was less
• than a third of its present age.
• The most distant quasar known to humans was
  detected in 2003. The light
• from this quasar was emitted when the
  universe was only 6 of its present
• age!
• Quasars radiate strongly across a wide portion
  of the electromagnetic
• spectrum with prominent spectral lines.
• This implies that the matter that makes up a
  quasar has a wide range
• of temperatures.

James J Marie, Astronomy 2005
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Quasars Revealed

• Quasars were initially thought to be strange
  new phenomena and new
• laws of physics would have to be discovered
  before we could understand
• them.
• The first clues about what quasars might be
  came from the spectra nearby
• galaxies with active nuclei.
• The spectra of quasars were very similar to
  active galaxies.
• This led to suspicion that quasars are actually
  galaxies with very energetic
• nuclei.
• The biggest difference between quasars and
  active galaxies is that quasars
• are far more luminous.

Quasars are associated with tremendously active
galactic nuclei seen from an early era of the
universe.
James J Marie, Astronomy 2005
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Compact Energy Sources

• The total luminosity or power output from
  quasars can vary rapidly in time.
• The rapid variation of luminosity
• implies that the radiated energy
• comes from a very small region
• of space.
• This region of space is no larger
• than the size of the solar system.
• Since quasars are so bright, the
• compact region (nucleus) is an
• unbelievable source of energy!
• The most powerful quasars
• have a luminosity of 2 trillion
• times that of the Sun (100 times
• more luminous than the entire
• Milky Way Galaxy)!

James J Marie, Astronomy 2005
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Radio Galaxies

• Radio galaxies are galaxies that emit unusually
  powerful radio waves
• from huge pairs of lobes on either side of the
  galaxy.
• The radio waves radiate from electrons and
  protons spiraling around
• magnetic fields at nearly the speed of light.

James J Marie, Astronomy 2005
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Radio Galaxies

• Radio galaxies are closely related to quasars
  because they also have
• very powerful active nuclei.
• Two incredibly energetic jets blast in opposite
  directions from the nuclei
• of radio galaxies.
• The jets carry blobs of plasma moving at nearly
  the speed of light!
• These blow torches feed energy to the radio
  lobes which are far outside
• of the visible galaxy.
• All of the energy that powers the jets and
  radio lobes comes from the tiny
• galactic nucleus!
• The total power output of a radio galaxy,
  implies that the nucleus of a radio
• galaxy is as powerful as the nucleus of a
  quasar.

James J Marie, Astronomy 2005
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Radio Galaxy Structure

• The lobes of a radio galaxy may lie
• as far away as a million light years
• away from the core.
• Many quasars also have a radio
• core-jet-lobe structure very similar
• to radio galaxies.
• The nuclei of many radio galaxies are
• hidden behind donut shaped rings
• of molecular clouds.
• If the orientation of the radio galaxy is
• such that the nucleus is visible from
• the donut hole, then the galaxy
• may appear very similar to a quasar.

James J Marie, Astronomy 2005
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Supermassive Black Holes

• The only known mechanism that can supply such a
  prodigious amount
• of energy from a volume of space as small as
  the nuclei of quasars
• and radio galaxies are supermassive black
  holes.

• Accretion disk feeding infalling
• matter into a black hole.

• This is an image of the AGN of
• NGC 4261 taken by the
• Hubble Space Telescope.
• The disk is 300 light years
• across and radio jets emanate
• from the plane of the disk.

James J Marie, Astronomy 2005
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An Awesome Powerhouse

• The potential energy of matter falling into the
  black hole is converted into kinetic
• energy.
• The added kinetic energy promotes violent
  collisions between atoms and the
• gas becomes super hot.

• The gas is ionized into a
• plasma which radiates
• energy in the form of
• ultraviolet radiation and
• x-rays.
• This is the most
• efficient process in
• the universe for
• generating energy!

James J Marie, Astronomy 2005
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Relativity at Work

• The amount of gravitational potential energy
  that gets converted into kinetic
• energy for a falling chunk of matter is
  equivalent to its mass energy, E mc2.

• Between 10 and 40
• of this energy is radiated
• away before it crosses
• the event horizon.
• This is far more efficient
• than energy production
• from nuclear fusion.
• The typical supermassive
• black hole in a quasar
• consumes about 17
• solar masses a year!

James J Marie, Astronomy 2005
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Primordial Quasar

• An artists impression of a primordial quasar
  that formed after the first few billion
• years of the universe is shown below.
• Primordial quasars might have been surrounded
  by sheets of gas, dust, stars and
• early star clusters.

• It is thought that most
• galaxies may have had
• a quasar phase when they
• were much younger.

James J Marie, Astronomy 2005
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Supermassive Black Holes and Galaxies

• It is presently believed that all galaxies
  probably harbor a supermassive black
• hole at their center.
• However it is not known how supermassive black
  holes are born.
• Nor is it known if the supermassive
• black holes formed before or after
• their host galaxies formed.
• This is one of the deepest
• mysteries in astronomy.

James J Marie, Astronomy 2005
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Galactic Neighborhood

• The nearest galaxies to the Milky Way are shown
  below in a 3-D map.

James J Marie, Astronomy 2005
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Local Group

• The local group is a cluster of galaxies which
  includes the Milky Way galaxy.
• Over 30 galaxies are included in the local
  group which spans 10 million light
• years across.

• The center of mass of
• the local group lies between
• the Milky Way Galaxy and
• the Andromeda Galaxy.
• The two largest galaxies of
• the local group are the Milky
• Way Galaxy and the
• Andromeda Galaxy.
• The total number of galaxies
• in the local group is not yet
• known.

James J Marie, Astronomy 2005
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Three Dimensional Map of the Local Group
James J Marie, Astronomy 2005
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Virgo Cluster

• The Virgo Cluster is the closest cluster of
  galaxies to our Milky Way Galaxy.
• The Virgo Cluster contains between 1300 and
  2000 galaxies.
• This cluster is so massive that it pulls the
  Local Group toward it.

• An image of the Virgo Cluster
• taken by the Palomar
• Observatory.

• All types of galaxies are seen
• including spiral, elliptical and
• irregular galaxies.

James J Marie, Astronomy 2005
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Closest Galactic Clusters

• Shown below is a three dimensional map of the
  closest galactic clusters.
• The Virgo Cluster is 62 million light years
  away from the Milky Way.

James J Marie, Astronomy 2005
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Virgo Supercluster

• The Virgo Supercluster is a
• supercluster of galaxies that
• contains the local group.
• It spans about 200 million
• light years and contains about
• 100 clusters and groups of
• galaxies dominated by the
• Virgo Cluster near the center.
• The total mass of the Virgo
• Supercluster is about one
• quadrillion solar masses.
• A gravitational anomaly called
• the great attractor is drawing
• in galaxies over a region
• hundreds of millions of light
• years across.

James J Marie, Astronomy 2005
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Large Scale Structure of the Universe

• In 1989, astronomers M. Geller and J. Huchra
  set out to map the large scale
• structure of the universe within a narrow
  slice.
• The distances to the galaxies were obtained by
  measuring the redshifts of
• very far galaxies.
• They found that galaxies are arranged into
  sheets and filaments.
• Clusters of galaxies are located at the
  intersections of these sheets.
• The sheets of galaxies surround giant
  bubble-like voids.
• An enormous sheet of galaxies called the Great
  Wall was discovered.
• The Great Wall is 500 million light years long
  and 200 million light years wide.
• Most astronomers believe that these
  large-scale structures grew from
• slight density enhancements in the early
  universe, just as galaxies did.

James J Marie, Astronomy 2005
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Slice of the Universe

• A thin slice of the universe extending to a
  distance of 700 million light years
• mapped out by Geller and Huchra is shown
  below.
• The tip of the slice coincides with the
  location of the Earth and each dot
• represents a galaxy.

• Large voids are
• seen under the
• arms of the stickman
• figure.

James J Marie, Astronomy 2005
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North and South Slices

• Large scale structure of slices
• of the universe as seen from the
• northern and southern
• hemispheres.
• Each of the 9,325 points
• represents a galaxy.
• The existence of the walls and
• voids are surprising since the
• matter distribution in the
• universe was originally thought
• to be uniform.
• Many theoretical ideas exist
• about the formation of these
• structures.

James J Marie, Astronomy 2005
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Deeper Slices

• A map of the galaxies has been extended into
  deeper slices measuring
• 4 billion light years in length.
• There is evidence that large structures in the
  universe may still be growing!

James J Marie, Astronomy 2005
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Galactic Map

• Shown below is a map of galaxies from a 15?
  patch of the sky.
• The positions of over 3 million galaxies are
  depicted by each point.
• It is seen that the universe appears more
  uniform at very large scales.

• Bright areas contain
• more galaxies than
• dark areas.
• The black rectangles
• are regions for which
• there are no data.

James J Marie, Astronomy 2005
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Gravitation and Structures

• Large structures in the universe are held
  together by the force of gravity.
• These structures include galaxies, clusters of
  galaxies, superclusters,
• enormous filaments and sheets of galaxies.
• The birth, evolution and fate of these
  structures are determined by the
• gravitational pull of mass that makes up the
  structures.
• The total mass contained in these structures is
  essential to understanding the
• evolution of the universe.
• To understand the evolution of large structures
  and the fate of the
• universe it is necessary to ask

How much mass is in the universe?
James J Marie, Astronomy 2005
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The Masses of Galaxies and Galactic Clusters

• To measure the mass in the universe we
• must survey the amount of mass in the
• galaxies.
• With galactic rotation curves we can weigh
• the galaxies.
• These curves suggest that galaxies
• contain far more mass than all the stars,
• gas and dust combined.
• This additional mass is not visible and is
• therefore called dark matter.
• The existence of dark matter implies that
• most of the universe is hidden from us!

James J Marie, Astronomy 2005
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Dark Matter

• This illustration depicts the
• the large spherical
• distribution of dark matter
• around a spiral galaxy.

• The amount of dark matter
• far exceeds the luminous
• matter in the galaxy.
• The radius of the dark matter
• sphere is typically 10 times
• the radius of the galactic
• halo.

James J Marie, Astronomy 2005
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Mystery of Dark Matter
What is dark matter?

• This is one of the great mysteries of
  cosmology.
• However, there are several ideas and we may
  already know a little about what
• makes up dark matter.
• We speculate that there are two types of dark
  matter

• Ordinary Matter
• Extraordinary Matter

James J Marie, Astronomy 2005
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Ordinary Dark Matter

• It is possible that at least part of the dark
  matter could be ordinary matter
• made up of protons, neutrons and electrons.
• Since protons and neutrons are called baryons,
  another name for ordinary
• matter is baryonic matter.
• In this case, dark matter simply refers to
  matter which doesnt glow as brightly
• as stars or hot gases.
• This implies that the Solar System, the Earth
  and human beings are dark
• matter.
• Since the universe is so vast, baryonic matter
  cannot be seen from great
• distances.

James J Marie, Astronomy 2005
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MACHOs

• Ordinary dark matter includes planets, brown
  dwarfs, Jupiter sized objects left
• over from the formation of the Milky Way and
  very dim low mass red stars.
• Such objects are called MAssive Compact Halo
  Objects.
• It is possible that trillions of MACHOs drift
  through galactic halos contributing
• to the masses of galaxies.
• MACHOs could also include black holes.
• We can only detect MACHOs with indirect methods
  such as gravitational
• lensing.
• A lensing event occurs when a MACHO drifts
  across our line of sight to a distant
• star.
• Indeed, if the galaxy is filled with trillions
  of MACHOs we should occasionally
• witness a rare lensing event involving a
  distant star.

James J Marie, Astronomy 2005
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Lensing of MACHOS

• If trillions of MACHOS really exist, a lensing
  event involving one star out of
• a million should occur every year.
• A lensing event is signaled by a
• star which temporarily brightens.
• The duration of the lensing event
• reveals the mass of the MACHO.
• Intensive large-scale projects to
• monitor lensing events have
• revealed the presence of MACHOs.
• However, there are not nearly
• enough MACHOs to account
• for all of the dark matter.
• Solar mass sized black holes
• have been eliminated as dark

James J Marie, Astronomy 2005
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Extraordinary Dark Matter

• Extraordinary dark matter is also known as
  nonbaryonic dark matter.
• Exotic particles of matter that interact very
  weakly with ordinary matter are
• predicted by some theories of high energy
  physics.
• These hypothetical Weakly Interacting Massive
  Particles are called WIMPs.
• WIMPs which are moving slow enough to collect
  in the halos of galaxies are
• referred to as cold dark matter.
• However, fast moving WIMPs that can escape the
  gravitational pull of galaxies
• are referred to as hot dark matter.
• Hot dark matter includes neutrinos which are
  moving at nearly the speed of
• light.
• It is possible that cold dark matter could make
  up most of the mass of the
• galaxies, but it is completely invisible in
  all wavelengths of light.

James J Marie, Astronomy 2005
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Balance of the Universe

• All of the mass in the entire universe
  collectively generates an enormous
• gravitational field.
• Since gravity is attractive, the universe is
  self attractive.
• In other words, gravity of the entire universe
  should slow the rate of
• expansion of the universe.
• The rate at which the expansion of the universe
  is slowed down is called the
• deceleration parameter.
• The amount of mass in the universe determines
  the rate at which the expansion
• slows down.
• The more mass there is, the more the expansion
  should slow down.

James J Marie, Astronomy 2005
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Geometry of the Universe

• Since gravity is the curvature of spacetime,
  the mass of the entire universe
• plays a role in determining the global
  geometry of the universe.
• The geometry of the universe can tell us
  whether the universe is finite or
• infinite.
• The amount of mass in the universe controls the
  rate at which the expansion
• slows down and the geometry of the universe.

What are the possibilities?
James J Marie, Astronomy 2005
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Zero Curvature

• One possibility is that the universe has just
  enough mass to slow the rate
• of expansion down after an infinite amount of
  time.
• If this is the case, the geometry of the
  universe is flat.

• A flat universe is destined to expand forever
  with the rate of expansion
• gradually slowing down to zero after an
  infinite amount of time.
• A flat universe is also unbounded and infinite.

James J Marie, Astronomy 2005
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Positive Curvature

• Another possibility is that the universe has
  more than enough mass to slow
• the rate of expansion down.
• At some time in the distant future, the
  expansion of the universe could stop
• and then reverse.

• In this case, the universe would be finite and
  unbounded.
• Such a universe is called a closed universe.

James J Marie, Astronomy 2005
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Negative Curvature

• A third possibility is that the universe does
  not have enough mass stop the
• expansion.
• In this case, the universe would have no bounds
  and would continue to expand
• forever.

• Such a universe is infinite and is called an
  open universe.

James J Marie, Astronomy 2005
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Critical Density

• The critical density of the universe is the
  mean density at which the universe
• would balance between collapse and eternal
  expansion.
• If the density of the universe is less than the
  critical density, then the universe
• will expand forever.
• If the density universe of the universe is more
  than the critical density, then the
• expansion will eventually stop and the
  universe will collapse upon itself.
• Present calculations tell us that the critical
  density is about 10-29 grams per
• cubic centimeter.
• This is roughly equivalent to a few hydrogen
  atoms in a volume the size of a
• closet.

Does the universe have the critical density?
James J Marie, Astronomy 2005
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Density of the Universe

• All of the luminous matter in the universe
  appears to add up to only about
• 1 of the critical density.
• So is there enough dark matter in the universe
  to stop the expansion?
• Our best estimates from clusters of galaxies
  and large scale structures is that
• all of the dark matter seems to add up to only
  about 30 of the critical density.
• Based on our present knowledge, it appears that
  the universe is infinite and will
• continue to expand forever.

James J Marie, Astronomy 2005
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A Shocking Discovery

• In 1998, a ten year study called the Supernova
  Cosmology Project measured
• distances to very distant galaxies using type
  Ia supernova as standard candles.
• The primary goal of the project was to measure
  changes in the rate of
• expansion of the universe (deceleration
  parameter).
• It was discovered that the expansion of the
  universe is not slowing down but
• instead, is accelerating!
• This discovery is shocking because it has no
  known explanation.

What could cause the expansion of the universe to
accelerate?
James J Marie, Astronomy 2005
48
Dark Energy

• The mysterious nature the drives the
  acceleration of the expansion of the
• universe is called dark energy.
• It has the nature of energy but no one knows
  for sure what it is.
• Strong negative pressure is associated with
  dark energy.
• The negative pressure effectively acts as
  repulsive gravity!
• Two sources of dark energy have been proposed

• Cosmological Constant A constant uniform energy
  density filling the
• vacuum of space. The vacuum is filled with
  the creation and annihilation
• of virtual matter antimatter particles.
• Quintessence A dynamic field whose energy
  density can vary in space
• and time.

James J Marie, Astronomy 2005
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What Kind of Universe Do We Live In?

• The accelerating universe adds uncertainty
  about the kind of universe we are
• living in.

? Dark energy could propel a closed universe to
eternal expansion.
James J Marie, Astronomy 2005
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A Negatively Curved Universe?

• It is possible, although not likely, that
  systematic distortions such as a novel
• form of light absorption by intergalactic dust
  may cause distant supernova
• to appear deceptively fainter.

• The fainter supernova could mimic the
  acceleration
• of the expanding universe.
• While it may be too soon to rule out a
  negatively
• curved universe, there is independent evidence
  
• against it.

• This diagram depicts a universe of negative
  curvature
• undergoing expansion.

James J Marie, Astronomy 2005
51
A Flat Universe

• There is considerable evidence that the
  universe is probably flat.
• However, it seems miraculous that the universe
  should be perfectly flat
• since this is such an unlikely possibility.

• Why should the universe be flat?
• A theory called inflation seems to provide a
• reasonable answer.
• But we still do not know with absolute
  certainty.

James J Marie, Astronomy 2005
52
The Cosmos

• Dark energy is the most dominant component of
  the cosmos.
• Presently, we think the universe is

73 dark energy 23 dark matter 4 ordinary
matter

• The universe is thought to be infinite and to
  have had a beginning.
• The latest estimate on the age of the universe
  is 13.7 0.2 billion years old.

James J Marie, Astronomy 2005